Publishing node information

ABSTRACT

The invention can enable routers in a region to share information about nodes on foreign sub-networks. The information includes the nodes&#39; and routers&#39; respective network layer addresses. Upon receiving a message addressed to one of the nodes, a router can tunnel the message to a router on the node&#39;s foreign sub-network for subsequent de-tunneling and delivery to the node.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application relates to U.S. patent application Ser. No. 09/736/807 entitled DELIVERING MESSAGES TO A NODE AT A FOREIGN NETWORK; and U.S. patent application Ser. No. 09/736,834, entitled ROUTING MESSAGES BETWEEN NODES AT A FOREIGN SUB-NETWORK; and U.S. patent application Ser. No. 09/736,827, entitled NETWORK COMMUNICATION BETWEEN HOSTS. These applications were filed on the same day as the present application and are incorporated by reference in their entirety herein. This application claims priority from U.S. Provisional Ser. No. 60/232,524, filed Sep. 14, 2000, entitled SEAMLESS IP COMMUNICATION IN A HIGHLY MOBILE ENVIRONMENT, incorporated by reference in its entirety herein.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

Work described herein was supported by government contract F30602-97-C-0340 awarded by the U.S. Air Force. The United States Government may have certain rights.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to network message delivery to network nodes.

2. Description of Related Art

Computer networks enable widely separated users and computers to exchange messages. Since computers exchanging messages rarely share a direct connection, messages (“datagrams”) often wend their way through a number of network routers that incrementally advance a message towards its destination. Just as a street address on an envelope identifies a particular home to a mail carrier, a network address identifies a particular node (e.g., a computer) on a network. By examining a destination network address of a message, network routers can forward the message along a path from the message's source to the message's destination.

FIG. 1 shows an example of message delivery over a network. As shown in FIG. 1, a source computer 102 sends a message 106 to a destination computer 110 via a network 108 of routers (circles a-i). As shown, the message 106 includes the network address (“10.1.98.49”) of the destination node 110. The destination address shown is an IP (Internet Protocol) address. An IP address is an example of a network layer address. As shown, the IP address can be expressed in a notation that uses a string of numbers separated by periods, with each number identifying eight bits of the IP address.

Routers typically maintain routing tables that store information on how to forward messages destined for particular IP addresses. For example, a routing table maintained by router “a” may include an entry that specifies that messages destined to IP address “10.1.98.49” should be forwarded to router “e”.

Because of the vast number of devices that may reside on a network, a routing table having an individual entry for each individual IP address could grow so large that looking up an IP address in a routing table could significantly slow down the routers. Thus, in addition to particular IP addresses, routers can store entries that specify a range of IP addresses.

A range of addresses can be specified using a notation similar to that used to specify a single IP address. To specify a range of addresses, a mask length follows a particular address. The mask length identifies the starting bits or “network prefix” shared by addresses in the range of addresses. For example, a range of IP addresses may be expressed as “10.1.98.0/24”, where the number after the “/” specifies a mask length of 24-bits (i.e., the “10.1.98” of the “10.1.98.49” address). Thus, “10.1.98.0/24” specifies a range of IP addresses that extends from “10.1.98.0” to “10.1.98.255”. That is, “10.1.98.0” to “10.1.98.255” both have the same network prefix of “10.1.98.”.

As shown in FIG. 1, the destination computer 110 of message 106 resides on a sub-network 104 b of devices having IP addresses in the range specified by “10.1.98.48/29”. Thus, different network routers may store a routing table entry for the range “10.1.98.48/29”. Messages bound for the sub-network 104 b eventually reach a gateway 109 that may store individual routing entries for IP addresses on the sub-network 104 b. The gateway 109 is somewhat analogous to a local post office that collects mail for homes in a particular zip code before dispatching the mail to particular homes.

The message delivery scheme described above rests on an assumption that once assigned an IP address, a node does not move to a different sub-network. With the advent of mobile devices (e.g., laptop computers, wireless phones, and wireless PDAs (Personal Digital Assistants)), devices having IP addresses are increasingly likely to change their point of attachment while in use. FIGS. 2 and 3 illustrate a potential problem caused by this mobility.

FIG. 2 shows a wireless mobile node 110 a attached to a sub-network 104 b. As shown, the IP address of the mobile node 110 a (“10.1.98.49”) is within the range of IP addresses (“10.1.98.48/29”) serviced by the sub-network 104 b. As such, the sub-network 104 b is referred to as the mobile node's 110 a “home network” or “topologically correct sub-network”. When the mobile node 110 a remains at its home network 104 b, the network 108 delivers messages 106 to the mobile node 110 a as described in conjunction with FIG. 1.

In FIG. 3, however, the mobile node 110 a has changed its point of attachment. For example, a user may have unplugged a laptop from a home network LAN (Local Area Network) 104 b, brought their laptop on a flight across the country, and established a connection with a foreign sub-network 104 c (i.e., a sub-network other than the home sub-network 104 b). After this movement, however, the IP address of mobile node 110 a is not within the range of IP addresses (“10.1.98.24/29”) handled by the foreign sub-network 104 c. As shown in FIG. 3, while network routers continue to forward messages 106 destined for the mobile node 110 a to the node's 110 a home network 104 b, the mobile node 110 a is no longer on the home network 104 b. In these circumstances, the home network 104 b will typically drop messages 106 addressed to the mobile node 110 a.

Several solutions to problems posed by mobile network nodes have been developed. For example, FIG. 4 illustrates a registration process used in mobile IP systems. In the registration process, a mobile node 110 a notifies a foreign agent 112 of the node's 110 a presence on the foreign network 104 c. The foreign agent 112, in turn, notifies a home agent 114 on the mobile node's 110 a behalf. Registration fails if communication with the home agent 114 fails.

If registration succeeds, upon receipt of a message 106 addressed to the mobile node 110 a, the home agent 114 tunnels the message 106 to the foreign agent 112. Tunneling is much like taking an entire envelope and stuffing it into yet another envelope addressed to a different street address. The foreign agent 112, in turn, de-tunnels and forwards the messages to the mobile node 110 a.

BRIEF SUMMARY OF THE INVENTION

The invention can enable routers in a region to share information about nodes on foreign sub-networks. The information can include the nodes' and routers' respective network layer addresses. Upon receiving a message addressed to one of the nodes, a router can tunnel the message to a router on the node's foreign sub-network for subsequent de-tunneling and delivery to the node. Thus, by publishing information about the nodes, even when communication with a node's home agent fails or is never established, a node on a foreign sub-network can continue to receive network messages from other nodes and routers in the region.

Other advantages will become apparent in view of the following description, including the figures and the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1-4 are diagrams illustrating network delivery of a message to a mobile node.

FIGS. 5-6 are diagrams illustrating establishment of local and remote bindings.

FIG. 7 is a diagram illustrating multiple remote bindings established by a mobile node.

FIG. 8 is a flow-chart of a process for establishing multiple remote bindings.

FIGS. 9-11 are diagrams illustrating publication of mobile node information.

FIG. 12 is a diagram illustrating delivery of a message to a mobile node.

FIG. 13 is a diagram illustrating movement of a mobile node.

FIG. 14 is a flow-chart of a process for transmitting mobile node information.

FIGS. 15 to 17 are diagrams illustrating delivery of messages between mobile nodes sharing a foreign agent.

FIG. 18 is a flow-chart of a process for delivering messages between mobile nodes sharing a foreign agent.

FIGS. 19 to 23 are diagrams illustrating peer-to-peer communication between mobile nodes.

FIG. 24 is a flow-chart of a process for peer-to-peer communication between mobile nodes.

FIG. 25 is a diagram of a computer.

DETAILED DESCRIPTION

A home and foreign agent can cooperate to deliver messages to a mobile node as the mobile node changes its point of attachment to a communication network. Sometimes, however, communication between the foreign and home agents may fail, for example, due to problems at the home agent or routers carrying messages between home and foreign agents. In such circumstances, the mobile node may find itself isolated and unable to receive IP (Internet Protocol) addressed messages. A variety of techniques, described below, can enable a mobile node to continue receiving IP addressed messages from other network nodes even when the mobile node fails to establish, or loses, connectivity with a home agent. In addition to preserving incoming message delivery, the techniques may place minimal, if any, burden on network resources.

Establishing Local and Remote Bindings

FIGS. 5 and 6 illustrate an approach that separates the task of establishing communication with a foreign agent 112 from the task of establishing a home agent 114. As described below, establishment of a foreign agent can play a part in message delivery even if an attempt to establish communication with a home agent fails.

As shown in FIG. 5, a mobile node 110 a has established a local binding with a foreign agent 112 on a foreign sub-network 104 c. The process of establishing a local binding between a foreign agent 112 and mobile node 110 a may proceed in a variety of ways. For example, the foreign agent 112 may send a message to a multicast address declaring its availability. This message can include information such as the services the foreign agent offers (e.g., reverse tunneling) and information about planned outages, capacity, and so forth. When a mobile node 110 a establishes a link layer connection to a foreign sub-network 104 c, the mobile node 110 a can await messages sent to the multicast address by the foreign agent 112. Upon receipt of such a message, the mobile node 110 a may send the foreign agent 112 the mobile node's 110 a IP address and a link layer address (e.g., an address that identifies the endpoint of a physical link between the foreign agent 112 and the mobile node 110 a). The foreign agent 112 can create a routing table entry for the mobile node's 110 a IP address and link layer address and, thereafter, deliver messages addressed to the mobile node's 110 a IP address using the corresponding link layer address. The process described is one example of the creation of a local binding between the mobile node 110 and the foreign agent 112.

As shown in FIG. 6, after establishing a local binding with a foreign agent 112, the mobile node 110 can attempt to send its IP address and the IP address of its foreign agent 112 to a home agent 114. This can establish a remote binding between the mobile node 110 a and the home agent 114. Thereafter, the home agent 114 can tunnel messages received at the mobile node's 110 a home network 104 b to the mobile node's 110 a foreign agent 112 for de-tunneling and delivery to the mobile node 110 a.

While FIG. 6 shows successful establishment of a remote binding with the mobile node's 110 a home agent 114, the mobile node's 110 a local binding with its foreign agent 112 can remain intact even if the attempt to establish a remote binding fails. This permits varying degrees of message delivery to continue even though communication with a home agent 114 is interrupted or fails from the outset.

As shown in FIG. 7, in addition to, or as an alternative to, establishing a remote binding with a home agent 114 on the mobile node's 110 a home network 104 b, a mobile node 110 a can establish remote bindings with one or more nodes 180 (“correspondent nodes”) on foreign sub-networks. For example, as shown in FIG. 7, the mobile node 110 a has established a remote binding with foreign sub-network nodes 180 a and 180 b in addition to a remote binding with a home agent 114 on the mobile node's 110 a home sub-network.

Establishment of a remote binding with a node 180 on a foreign sub-network can occur without the involvement or establishing communication with a home agent 114. For example, when the mobile node 110 a sends a message to a correspondent node 180 a and expects a reply, the mobile node 110 a can also send the node 180 the mobile node's IP address and the IP address of its foreign agent 112. Thereafter, a correspondent node 180 a can tunnel messages to the mobile node's 110 a foreign agent 112 for de-tunneling and delivery to the mobile node 110 a. The tunneled message need not pass through any part of the mobile node's 110 a home network 104 b. This may not only reduce message delivery time by eliminating a routing detour to the mobile node's 110 home agent 114, but permits message delivery to a mobile node in the absence of communication with a home agent 114.

FIG. 8 depicts a flow-chart 200 describing an example of a process for establishing a remote binding with a node on a foreign sub-network. As shown in FIG. 8, a mobile node, or another node having knowledge of the mobile node's IP address and the IP address of the mobile node's foreign agent, may initiate establishment (step 202) of a remote binding for the mobile node. For example, a router having a remote binding with a mobile node may receive a message addressed to the mobile node. In such a case the router can establish a remote binding with the message sender on behalf of the mobile node. Thereafter, regardless of the entity initiating establishment of a remote binding, the sender can tunnel (step 204) messages directly to the mobile node's foreign agent for subsequent delivery (step 206) to the mobile node. Again, this process does not require communication with the mobile node's home agent.

Publishing Node Information

FIGS. 9 to 13 illustrate other techniques that can enable a mobile node to continue to receive IP messages from other network nodes in the absence of communication with a home agent. Essentially, each foreign agent publishes information about currently attached mobile nodes to other foreign agents and/or other routers. Routers/agents receiving the information can, for example, create routing table entries for the mobile nodes. When a foreign agent or other router receives a message addressed for delivery to a mobile node, the foreign agent or router can tunnel the message to the mobile node's foreign agent. The foreign agent, in turn, de-tunnels the message for delivery to the mobile node.

Such a scheme poses an important question: which foreign agents/routers should receive information about the mobile nodes? For example, publishing the local bindings of a foreign agent to each router on the Internet could generate an overwhelming amount of network traffic and could result in enormous routing tables. One solution involves programming each foreign agent or router with a complete or partial list of other routers/agents that should receive the information. For example, a collection of routers/agents that share such information (“a mobility region”) can be handcrafted by selecting network nodes for inclusion in the region and programming agent/routers in the region accordingly. In another approach, however, the mobility region may coincide with nodes in an autonomous system.

In greater detail, the Internet knits together many different autonomous systems. The term autonomous system does not denote a geographic relationship, but instead identifies an administratively defined region of routers that share information about the configuration of nodes (i.e., the topology) within the system. This information enables the routers in the autonomous system to determine a path for a message having a given destination network address. For example, many autonomous systems use a protocol known as OSPF (Open Short Path First) to route messages. In OSPF, each router floods the autonomous system with “link state advertisements” describing a metric (e.g., a time delay or link capacity) associated with reaching routers adjacent (i.e., within one “hop” or link) to itself. Each router in the autonomous system eventually receives information about costs associated with each connection (“link”) in the system. From received link state advertisements, a router can determine the current topology of the autonomous system and can identify paths through the set of routers that reach particular nodes or sub-networks. Other autonomous systems can use other routing protocols such as distance vector routing protocols.

FIGS. 9 to 13 illustrate how publishing information about locally bound mobile nodes can enable message delivery to the nodes when communication with a home agent is not available. As shown in FIG. 9, a foreign agent router 112 d maintains a routing table 122 d indicating how to route messages bound for different nodes in a region 120 (e.g., an autonomous system). As shown, the routing table 122 d lists an IP address and an adjacent router (i.e., a router one “hop” or “link” away) en route to the listed IP address. For example, the routing table 122 d indicates that a message bound for foreign agent 112 a should be forwarded to foreign agent 112 b. Similarly, the routing table 122 b for foreign agent 112 b, instructs the foreign agent 112 b to forward the message to foreign agent 112 a.

As shown in FIG. 10, mobile nodes 110 may establish local bindings with foreign agents 112 a-112 d in the region 120. To inform and update region routers 112 a-112 d, 118 of these local bindings, each foreign agent 112 a-112 d can publish information describing locally bound mobile nodes. Publishing may be performed in a variety of ways.

For example, FIG. 11 illustrates publishing by flooding. Flooding, in turn, may be done in a variety of ways. For example, an initial router 112 a can publish information 121 about locally bound nodes 110 a-110 g to each adjacent router (e.g., 112 c, 112 b). Routers receiving the information 121 for the first time can forward the information 121 to each adjacent router other than the router it received the information 121 from. Routers receiving the information 121 a second time can drop the information 121. As shown, flooding can quickly spread mobile node information 121 across the region 120. Though FIG. 11 only shows flooding initiated by one foreign agent 112 a, each foreign agent 112 a-112 d can flood a region 120 with information about locally bound mobile nodes 110 a-110 g. Thus, each area router/agent 112 a-112 d, 118 can locate a mobile node's 110 a-110 d foreign agent 112 a-112 d. The agents/routers 112 a-112 d, 118 can add entries for each mobile node 110 a-110 g to their routing tables 122 b, 122 d. For example, foreign agent 122 d can create a routing table 122 d entry for mobile nodes 110 a and 110 b.

Messages transmitted by a foreign agent 112 a-112 d to publish information of locally bound nodes 110 a-110 g may use a variety of data formats. Alternatively, such information can be included in messages normally exchanged by routers (e.g., OSPF opaque link state advertisements). Such messages need not include metric information describing the state of links between region routers/agents or other information for routing packets through the network, but may only include identification of a foreign agent 112 a-112 d and one or more mobile nodes 110 a-110 g locally bound to the foreign agent 112 a-112 d. Such messages should be coded such that their use does not interfere with operating routing protocols. Routers not participating in the scheme can ignore the content of the message.

As shown in FIG. 12, because of the publication of mobile node information, region routers 112 a-112 d, 118 can deliver messages using the IP address of a mobile node 110 a-110 g, without the intervention of a mobile node's home agent. For example, in FIG. 12, mobile node 110 g addresses a message to mobile node 110 a. Upon receipt of the message, foreign agent 112 d looks up a routing table 122 d entry for mobile node 110 a, and initiates tunneling of the message to the foreign agent 112 a of the destination mobile node 110 a. Tunneling enables delivery of the message even though intervening routers may not participate in the scheme. The foreign agent 112 a of the destination mobile node 110 a de-tunnels the tunneled message and forwards the de-tunneled message to the mobile node 110 a. Again, this enables mobile nodes 110 a-110 g in the area 120 to communicate using IP addresses even though a connection to a home agent may fail.

As illustrated, though messages received by a mobile node's 110 a-110 g foreign agent 112 a-112 d may be tunneled, the publishing information need not be tunneled. This can increase efficiency.

As mobile nodes move about, foreign agents 112 a-112 d may publish updated information. For example, after a mobile node 110 a terminates a local binding with an agent 112 a, the agent 112 a may flood the region 120 with a message indicating the agent 112 a no longer offers link layer (i.e., physical connectivity) with the node 110 a. A similar flooding may occur after a node 110 a establishes a new local binding. Additionally, agents 112 a-112 d may periodically flood information regardless of whether mobile nodes establish or terminate connections.

As shown in FIG. 13, a mobile node 110 c may be capable of communicating with more than one foreign agent 112 a, 112 b. In fact, in some implementations, a mobile node 110 c ranks foreign agents 112 a, 112 b in physical communication and establishes a local binding with the highest ranking agent. Such ranking may be based, for example, on services offered by the agents, capacity, signal strength, and so forth. The mobile node 110 c may periodically repeat the ranking process. This can enable the mobile node 110 c and routers to adapt to changes in network conditions and the mobile node's locations.

As shown in FIG. 13, mobile node 110 c establishes a local binding with foreign agent 112 a after having previously established a local binding with foreign agent 112 b. As shown, the local binding may trigger publishing of information 121 about the mobile node's 110 c new local binding. Such publishing may only be initiated after some holdoff time period (e.g., a few seconds) after initiating a previous publishing. The technique can enable a router to combine the information about mobile nodes into fewer messages.

Thus, as shown in FIG. 13, a mobile node 110 c may have local bindings with two foreign agents 112 a, 112 b at the same time. Further, a foreign agent 112 b having a local binding with a mobile node 110 c may receive a published message 121 initiated by a different foreign agent 112 a also having a local binding with the mobile node 110 c. To ensure continuous service, a foreign agent 112 may give precedence to a local binding over a published local binding. That is, until the mobile node 110 c terminates its local binding with foreign agent 112 b, foreign agent 112 b will disregard published local binding messages for the node 110 c and continue to deliver messages directly to mobile 110 c, instead of tunneling them to foreign agent 112 a.

FIG. 14 shows a flow-chart of a process 130 for publishing mobile node information in a region. In this example process, after a mobile node (step 132) establishes a local binding with a foreign agent, the foreign agent floods (step 134) area routers with a message describing a local binding with the mobile node. Routers receiving the message can update (step 136) their routing tables correspondingly. Thereafter, the routers can tunnel (step 138) messages to the mobile node without intervention of a home agent.

Again, sharing mobile node attachment information between routers in an area (or other defined set of routers) permits IP-based message delivery to mobile nodes without requiring the assistance of a home agent. Additionally, the technique permits IP-based message delivery to mobile nodes even in the event the entire area loses connectivity with any other region. That is, even if a communication link goes down, mobile nodes in a region can continue to exchange messages.

Routing Messages Between Nodes on a Foreign Sub-Network

Sharing the locations of mobile nodes between routers in a region can help provide IP-based message delivery without home agent intervention. Sometimes, however, communication between routers in an area may also suffer. For example, many networks feature mobile routers such as routers carried by planes or satellites. In such an environment, the mobile routers may be unavailable for periods of time.

FIGS. 15 to 17 illustrate a technique for providing message delivery to mobile nodes sharing a foreign agent. Thus, even in the event a foreign agent becomes isolated from other routers, mobile nodes sharing the foreign agent can continue to exchange messages.

As shown in FIG. 15, a foreign agent 112 periodically sends a message declaring the agent's 112 availability for providing service to mobile nodes 110 a-110 c. As shown in FIG. 16, after the mobile nodes 110 a-110 c respond, the foreign agent 112 can modify a routing table 140 to include entries for the mobile nodes 110 a-110 c. These entries can include the IP address of a mobile node 110 a-110 c and the node's link layer address (e.g., MAC (Media Access Control) Address). Thus, as shown in FIG. 17, when the foreign agent 112 receives an IP message 123 addressed to another mobile node 110 c having a local binding with the same foreign agent 112, the foreign agent 112 can send the message to the destination node 110 directly; without the use of the destination node's home agent or any other routers in an area. For example, as shown, the foreign agent 112 can receive an IP message 123 from mobile node A 110 a addressed to mobile node C 110 c and can send the message to mobile node C using the link layer address stored in the routing table 130.

FIG. 18 illustrates a process 150 for delivering messages between mobile nodes sharing a foreign agent. After a mobile node establishes (step 152) a local binding with a foreign agent (or the mobile node otherwise communicates its IP address and link layer information), the foreign agent can modify (step 154) a routing table to include information about the mobile node. Thereafter, when the foreign agent receives (step 156) a message addressed to node having a local binding, the foreign agent can forward the message (step 158) to the destination node. This technique can provide IP-based communication between mobile nodes, not only when connectivity fails between a mobile node and its home agent, but when the foreign agent finds itself unable to communicate with other agents/routers.

Host-To-Host Communication

In some circumstances, a mobile node may fail to communicate not only with a home agent, but may even fail to establish, or lose, connectivity with a foreign agent. Traditionally, in such circumstances, the mobile node may find itself isolated and unable to receive messages. FIGS. 19 to 23, however, illustrate a technique that enables a mobile node to communicate with other mobile nodes, even in the absence of contact with a foreign agent.

As shown in FIG. 19, a foreign agent 112 periodically advertises its availability to mobile nodes 110 a-110 c as describe above. As shown in FIG. 20, one of the mobile nodes 110 a receives the advertisement, is satisfied with the services offered by the foreign agent 112, and responds by establishing a local binding with the foreign agent. Mobile nodes 110 b, 110 c, however, fail to establish a physical link with the foreign agent 112. For example, the mobile nodes 110 b, 110 c may be beyond a radio transmission range of the foreign agent's 112 sub-network. Thus, mobile nodes 110 b, 110 c fail to establish local bindings with the foreign agent 112.

If a mobile node 110 b-110 c fails to contact a foreign agent 112, the mobile node 110 b-110 c may begin sending requests for service. For example, as shown in FIG. 21, failing to receive a response from a foreign agent 112, mobile nodes 110 b, 110 c can send messages requesting service. Such messages may request different levels of service. For example, in FIG. 21, the mobile nodes 110 b, 110 c request services that include routing (i.e., forwarding of messages received from one network node to another network node). The mobile nodes 110 b, 110 c may downgrade their requests until the node receives a response. For example, as shown in FIG. 22, if a request for routing services fails, the mobile nodes 110 b, 110 c can downgrade their service request to a request for communication with a host (i.e., a node not offering routing services).

As shown in FIG. 23, while mobile nodes 110 b, 110 c cannot establish communication with a foreign agent 112, nodes 110 b, 110 c can at least establish communication with each other 110 b-110 c, mobile node 110 a, and other hosts. That is, mobile node 110 b can exchange messages with mobile nodes 110 a and 110 c. While mobile nodes 110 a-110 c do not provide routing services (i.e., mobile node 110 b cannot forward a message from mobile node 110 a to mobile node 110 c and mobile node 110 a cannot forward message received on the sub-network), the mobile nodes 110 a-110 c can, nevertheless, exchange messages with adjacent mobile nodes 110 a-110 c. Thus, even when network conditions prevent communication with a foreign agent 112, these techniques can at least provide the mobile nodes with IP-based communication with other hosts.

FIG. 24 shows an example of a process 160 illustrated in FIGS. 17 to 21. After a mobile node solicits (step 162) router services and does not receive (step 164) a response, the mobile node can downgrade (step 168) the services requested until the mobile node requests contact with other hosts. Upon receiving (step 170) a response from another host and modifying the host's message forwarding table (step 172), the mobile node can exchange messages with the responding host.

Security

Messages that affect routing state should be authenticated. In particular, messages that may, in the course of proper operation, be received from arbitrary points on the network are particularly susceptible to spoofing attacks.

Messages between a mobile node and its home agent can use manual keying since there is presumably a close administrative relationship. A way to avoid manual keying is to use a key negotiation protocol based on public key cryptography and certificates. A straightforward choice within the domain of the Internet Protocol is to use the IPsec protocols (RFC 2401). This involves using either Authentication Header (AH, RFC 2402) or Encapsulating Security Payload (ESP, RFC 2406) to provide integrity and data origin authentication for the binding requests. Also, one can use the Internet Key Exchange (IKE, RFC 2409), which includes the Internet Security Association and Key Management Protocol (ISAKMP, RFC 2408) and the OAKLEY Key Determination Protocol (RFC 2412). However, IKE requires the two nodes wishing to establish a security association to exchange messages. However, a node attempting to establish a local binding is typically not at its topologically correct location. Therefore, messages from the responding node are sent via normal routing to the mobile node's home sub-network, rather than to the node's current location. So, key exchange requires modifying the routing table. Since key exchange is not yet complete during key exchange, this requires modifying the routing table based on an unauthenticated message.

Another solution is based upon sending the IKE reply message other than via normal routing, and conveying in the IKE messages the information necessary to send the reply message. In the case of a local binding, the mobile node is the IKE Initiator, and a foreign agent is the IKE Responder. The mobile node includes in its IKE messages to the foreign agent an extension which contains the link layer address of the mobile node (typically the Ethernet address, in the case of wired Ethernets or Ethernet-like wireless LANs). The foreign agent, as Responder, sends the reply message not via normal routing, but via the physical interface over which it received the mobile node's message. The link layer destination of the reply is set to the address contained in the mobile node's IKE extension message. No record of the link layer address is kept at the foreign agent; the extension is present on every message from the mobile node. In this way, the mobile node and foreign agent can complete a security association after the exchange of several pairs of messages. Then, the mobile node can obtain an authenticated agent advertisement from the foreign agent, send an authenticated local binding request, and obtain an authenticated reply.

The case of a remote binding is similar. The mobile node has already obtained a local binding. Rather than including the link layer address in the extension message, the mobile node includes a notation that the reply message should be tunneled and the care-of address (COA) for its local binding. The corresponding host (which may be the home agent) is the IKE responder and sends the IKE reply encapsulated with an outer destination of the IP address contained in the IKE extension. Again, the corresponding host keeps no record of the care-of address of the mobile node; the extension is present on every message from the mobile node.

The format of the extension message is not critical. A simple method would be to have a code word which either means “link layer address” or “IP address for tunneling”, followed by a length in bytes for the address and the address data itself. An implementation of this technique on an existing operating system may turn out to be somewhat awkward, since operating systems typically have a routing table but do not have operations to send packets via alternate routes. In such cases, a shortcut which eases the implementation work but has a minor degradation in security properties may be deemed acceptable. The shortcut consists of temporarily modifying the routing table to forward messages for the mobile node to either its alleged link layer address or care-of address, sending the IKE response message, and then restoring the routing table to its previous contents. If no other messages are sent to the mobile node during the time the routing table is in this temporary state, this implementation shortcut is not visible from the behavior of the machine. The risk is that some number of packets intended for the mobile node may be misdirected in either the case that the IKE request is from some entity which is not the mobile node or the case that the IKE request has been modified in transit. If this shortcut is used on a system implemented with an operating system kernel and daemons in separate address spaces for the mobility protocol and key management, it may be convenient for the IKE daemon to request of the mobility protocol daemon that these temporary routing table changes occur. A sequence could proceed:

-   -   (1) IKE requests Mobility to install temporary route     -   (2) Mobility installs temporary route, removing any previous         route     -   (3) Mobility acknowledges to IKE that the route is installed     -   (4) IKE sends the message     -   (5) IKE informs Mobility that the temporary route is no longer         needed     -   (6) Mobility removes the temporary route and installs the proper         route     -   (7) Mobility acknowledges to IKE that the operation is complete.         Alternatively, (6) could be performed after some timeout         after (2) or (3) in the event (5) does not occur, to guard         against persistent errors in the case of failure of the IKE         daemon.         Implementations

Different implementations may include one or more of the techniques described above. Additionally, implementations may include a variety of different features. For example, local and remote bindings may have limited lifetimes.

The techniques described herein are not limited to any particular hardware or software configuration; they may find applicability in any computing or processing environment. The techniques may be implemented in hardware or software instructions, or a combination of the two. Preferably, as shown in FIG. 25, the techniques are implemented in computer programs executing on programmable computer 200 that includes a processor 202, a storage medium readable by the processor (including volatile 204 and non-volatile 206 memory and/or storage elements). The computer may also feature one or more wireless and/or wire network connections 208. Such a computer may be any of the entities described herein (e.g., router, host, or other network node).

Each program is preferably implemented in high level procedural or object oriented programming language to communicate with a computer system. However, the programs can be implemented in assembly or machine language, if desired. In any case the language may be compiled or interpreted language.

Each such computer program is preferably stored on a storage medium or device (e.g., CD-ROM, hard disk, or magnetic disk) that is readable by a general or special purpose programmable computer for configuring and operating the computer when the storage medium or device is read by the computer to perform the procedures described herein. The system may also be considered to be implemented as a computer-readable storage medium, configured with a computer program, where the storage medium so configured causes a computer to operate in a specific and predefined manner.

Other embodiments are within the scope of the following claims. 

1. A method for use in delivering network messages, the method comprising: (a) receiving at a first router a network layer address of a node, the first router and the node both being on a sub-network that is topologically foreign with respect to the network layer address of the node; (b) sending from the first router the received network layer address of the node and a network layer address of the first router toward a second router, the second router being on a sub-network that is topologically foreign with respect to the network layer address of the node; (c) receiving at the first router a message tunneled toward the first router by the second router in response to receiving a message at the second router having a destination address of the node; (d) de-tunneling the tunneled message; and (e) sending the de-tunneled message toward the node; whereby (a)-(e) proceed without requiring communication with any node on a sub-network that is a topologically home sub-network with respect to the network layer address of the nodes.
 2. The method of claim 1, wherein the second router comprises a router in a defined collection of routers.
 3. The method of claim 2, wherein the defined collection of routers comprise routers within an autonomous system.
 4. The method of claim 3, wherein the defined collection of routers within an autonomous system comprise routers within an OSPF (Open Short Path First) system.
 5. The method of claim 2, wherein the defined collection of network nodes comprises routers in more than one autonomous system.
 6. The method of claim 2, wherein sending the received network layer address of the node and a network layer address of the first router toward a second router comprises flooding the defined collection of routers with the received network layer address of the node and the network layer address of the first router.
 7. The method of claim 1, wherein the network layer address of the node comprises an Internet Protocol address.
 8. The method of claim 1, wherein the node comprises a wireless node.
 9. The method of claim 1, further comprising determining whether to send the received network layer address of the node and a network layer address of the first router.
 10. The method of claim 9, wherein determining comprises comparing a time elapsed since a previous sending of a received network layer address of a node with a holdoff period.
 11. The method of claim 1, further comprising advertising availability of the router to serve mobile nodes.
 12. The method of claim 1, wherein sending the received network layer address of the node and the network layer address of the first router toward a second router comprises sending without tunneling.
 13. A computer program product, disposed on a computer readable medium, for use in delivering network messages, the computer program including instructions for causing a processor to: (a) receive at a first router a network layer address of a node, the first router and the node both being on a sub-network that is topologically foreign with respect to the network layer address of the node; (b) send from the first router the received network layer address of the node and a network layer address of the first router toward a second router, the second router being on a sub-network that is topologically foreign with respect to the network layer address of the node; (c) receive at the first router a message tunneled toward the first router by the second router in response to receiving a message at the second router having a destination address of the node; (d) de-tunnel the tunneled message; and (e) send the de-tunneled message toward the node; wherein (a)-(e) proceed without requiring communication with any node on a sub-network that is a topologically home sub-network with respect to the network layer address of the node.
 14. The computer program of claim 13, wherein the second router comprises a router in a defined collection of routers.
 15. The computer program of claim 14, wherein the defined collection of routers comprise routers within an autonomous system.
 16. The computer program of claim 15, wherein the defined collection of routers within an autonomous system comprise routers within an OSPF (Open Short Path First) system.
 17. The computer program of claim 14, wherein the defined collection of network nodes comprises routers in more than one autonomous system.
 18. The computer program of claim 14, wherein the instructions for causing a processor to send the received network layer address of the node and a network layer address of the first router toward a second router comprise instructions for causing a processor to initiate flooding of the defined collection of routers with the received network layer address of the node and the network layer address of the first router.
 19. The computer program of claim 13, wherein the network layer address of the node comprises an Internet Protocol address.
 20. The computer program of claim 13, wherein the node comprises a wireless node.
 21. The computer program of claim 13, wherein sending the received network layer address of the node and the network layer address of the first router toward a second router comprises sending without tunneling. 